High-pressure gas-producer.



5 lSHIJETB--SHEET 1.

No. 993,192. I PATENTED JULY '14, 1908.

E. E. NOYES 9 S. A. EEEVE.

:HIGH PRESSURE GAS PEUDUUEE.

9 APPLICATION FILED 'JULY 26. v1905. 4

r -SHBBTS-BHEET 2.

No. 893,192. l PATENTED JULY 14. 1.908. E. P. NOYBS & S. A.- REEVE. HIGH PRLTSSIRL. GAS P RODUGEE.

5 SHEETBr--SHEBT 3.

y ff@ J9-. i f @w l Y (/z No. 893,192. PATENTED JULY 414, 1908. E.4 P. NOYES & S. Ai REEVE, HIGH PRESSURE GAS P-R01)G}R APPLmATIoN FILED' JULY 26. 1905.

s' SHEETS-81mm' 4.

No. 893.192. PATBNTED JULY 14, 1908.

1:.v P. NOYBS & s. A. REE-VE. HIGH PRESSURE GAS PRODUCER.

APPLIGTIONPILED JULY 25. 1905.

`\ g J j@ MM i; rnrnn o ric EDWARD P. NOYES, OF WINCHESTER, ANDSIDXEY A. REEVE, OF WORCESTER, MASSACHU- SETTS, ASSIGNORS TO CHARLES F. BROWN, TRUSTEE, 0F READING, MASSACHUSETTS.

. HIGH-PRESSURE GAS-PRODUCER.

Speecation of Letters Patent.

Patented July 14, 1908.

Application mea July 26, 190s. serai No. 271,268.

ing specification and accompanying drawings illustrate one forni of ythe invention, which we now regard as the best out-of the various forms in 'which it may be embodied.

Our invention relates to gas-generators for making gas under pressure by passing compressed air through a bed of burning coal and its main features apply principally to fuel-gas generators known as roducers, using. a deep bed of fuel, though a so applicable to 'mternal-oombustion` engine systems inwhic-h a coal-furnace with a thin fuel-bed is sealed and operated under pressure. The

`air-pressure which we prefer touseis something higher thana mere fan blast or light pump-pressure such as is used to supply the draft in producers commonly known as "pressure producers (to distinguish them from suction producers) for su plying l' Te propose to place our roducer in a compressedair line between t ie combustion-cyllnder or other burner of a multi-cylinder engine system,4 and an air compressor forming .an integral part of said system, and this accordmgly requires that the generating chamber of the producer be sea-led against the escape in any considerable quantity, of its gaseous contents at times of fuel-feeding and ashremoval. Certain improved feeding, sealing and ash-removing devices for accomplishing this result form the subject of our present application.

l Tl'ie `accompanying drawings show a constructive en'xbodinlent selected for illusira ting i he manner of carrying out the invention. 4

Figure 1 represents a diagrammatic view el the whole apparatus. Fig. i2 represents a top-plan view of tlie'pro lu -cr. .F1g 3 rcprcwnts un elevation of the fuel-feeding and adjx'w'cnt devircs partly 1n. section, and omitting certain parts more f ully 'dun in Fig. 5': Fig 4. represents anenlarged ci tical lin said devices.

section of the producer and adjacent parts. Fig.' 5 re resents an enlarged section of the devloes for actuating the coal-metering valves. Figs. 6 and 6a represent sections on the correspondingly-numbered lines of Fig. 3. Fig. 7 represents a section on line 77 of Fig. 6. Figs. 8 and 9 represent vertical sections of the upper and lower valves constituting a part. of the fuel-lock by which pressure in the generator is conserved at times of fuel feed thereto. Fig. 10 represents 'a section on line 10--10 of Fig. 9. Fig. 11 represents an isometric view of certain hydraulic cylinders and connected mechanisms included in the fuel.- feeding devices. Fi s. 12 and 13 are detail end and sectiona views of trip-latches included Fig. l14 is a sectional view of the pump for furnishing ythe water-circulation. Fig. 15 is a section on line -15-15 of Fig. 14. Fig. 16 (Sheet 2)is a vertical section of one of the hydraulic cylinders ofthe fuel-feeding devices. lsig. 17 (Sheet 4) represents an end view of the hydraulic cylinders and connections. lig. 18 is a vertical section showing a balance-controlled 'valve for introducing an excess of discharge from the hydraulic cylinders into the water-seal in the fuel-conduit.

We will first enumerate the principal elements shown in the drawings and describe their operation in a general way. The producer shown is of the down draft type. Both ends are water-sealed so that no appreciable amount of pressure-gas can escape during periods of fuel-introduction and ashremoval, and through the upper seal fuel is introduced in predetermined. quantities. This may if desired be done automatically to suit the rate of gas-consumption. ln combination with the seal, novel arrangements are provided constituting a pressure lock. The feeding is eHected by the use of hydraulic devices for operating the valves, etc. of the automatic stoking mechanism, and these devices include an arrangement whereby the pump which furnishes the power for said devices can have its output varied to regulate the rate of fuel-supply. Novel prpvisions are made for iiushing the valve fin the fuel-feeding line to enable them to. close-105 tight. T he air enters the producer through the column of green and wet fuel emerging from the water-seal at the feeding end. On

. thereby cleansed'of some of its impuritiesl.

issuing from the producer-chamber the gas passes through the lower water-seal andis For maintaining the water in the different seals and bodies of water at constant levels, automatic level-controllers are employed.

' Referring n'ow in detail to the drawings,

34 is a down-draft gas-producer having at its upper end an inlet for solid fuel supplied through av fuel-conduit 35, 'and atv the vsame end receiving compressed air through a pipe 36, said air entering an ascending leg of the column of green fuel.I A suitable amount of .steam may accompany the ,air as is common 1n producers of theDowson type. 1n this l producerthe generating chamber 38 is shown double-walled, with an annular space 39 for the formation of atraveling ash-'envelop to surround the lowenend of the fuel-column at its hottest part and "prevent scaffolding and the lodgment of clinkers. An inner section of the chamber wall is made with a water-jacket 40 terminating at a point above the lower end '.of the chamber, and by this combination of water-jacket' and traveling lining formed of the ash or earthy remains of the fuel we avoid the use of a fire-brick lining. There is also an oscillating annular ash-sifter 66 with shaking means including rod 67 (Fig.

2) toggle 68, slide .69 and crank-pin 70 on wheel 71, the latter driven by a be t 72 from wheel r74cm a countershaft 164. The ashlining features however, are incompletely shown and not included in our present appli-v cation.

.'The fuel-column is supported on a slowlyrevolving flat-conical hearth-plate'41, madeV tubular member 53 entering an ash-pit 54.

These details may be varied, and mechanical knowledge is also sufficient, without special description by us, to vary the direction of air and gas flow so as to make an up-draft producer.

In the ash-pit is a body of water 55 occupying the gas outletand serving as a Washer or cleanser of t-he gas, condensing its impuri-` ties and precipitating its soot and dust, and

also quenching the ashes. The water-seal is preferably fed through, Vand maintained at `a predetermined level by, an automatlc levelcontroller 56. At the convergent bottom of the ash-pit we provide in connection with the seal -a pressure lock including an ash-discharge pipe', admission-valve 58 thereto at the upper end o erated by hydraulic c linder 59 with its va ve hand-controlled by ever 60, 'and discharge-gate 61 at the lower end.

seams To dischar e the ashes the upper valve is o ened to t en 'closed and the lower discharge-gate 61 opened. Pressures are equalized above and' 4below the valve at the time of opening of said valve by a byass 580 -connecting the ashpit 54 with the ook-chamber 57 and containing a'stop-valve 581. At times' of ash-removal the body of water seals the pressure lock4 against the escape of gas in any considerable quantity, each discharge being a lockfull of water and ashes with only dissolved gas.

From the top of the chamber 57 (Fig. 4) opens a pipe 1001 leading into a separator c amber 1002. The bottom of the'separator is connected with lock-chamber 57 by a ipe 1003 which enters 57 at a point lower tran pipe 1001. From the to of chamber 1002 opens pi e 1004 through 't 1e cock 1005 which `may lea to any suitable point in the systemsup lied by the producer. The o ening of coc 1005 is preferably made qulte small. From the pipe 1003 a branch opens to the atmosphere through the cock 1006. When a charge of ashes and water has been drawn from the ash-pit 55 into lock-chamber 57 and the valve 58 closed, cock 1006 is opened slightly, letting enough water go to waste to slightly lower the pressure in 57 and to leave a small s ace above the water in it. ACock 1006 is tien closed and cock 1005 opened. This further lowers the pressure in 57 so that any gas-which may have become dissolved in the water is caused to separate from the water and to pass through conduit 1004 to a suitable point of use.

1007 is a tank open to the atmos here and containing a body ofwater 1008 w rich seals the discharge gate 61 of chamber ,57 and serves as a catch-basin for the rush of ashes and water when 61.is opened. A flushing and replenishing action insuring maintenance of the Water-seal during the ash-dischar e is effected by .a body of water in an auxi iary reservoir 62 having a discharge-and-vent branch-connection 63 with the ash-pit, 'controlled by the Water therein. An upper vent 64 when opened` allows reservoir 62 to fill from the water-seal. The gas collecting above the water'in reservoir 62 may be led olf through a pipe 1009 andused in the system. 188 is an" off-take pipe for conducting the gas to the point of use.

Fuel-feeding arrangements are as follows: 95 isa fuel-hopper discharging to the first or atmosphericressure section 96 of the fuel conduit 35. Lln this section are metering devices for feeding predetermined quantities of fuelpat redetermmed periods to the fuel lock. These evices consist as here shown of a pair of concurrently-operating upper and lower valves 97 and an alternately-operating middle valve 98. The valves 97 are actuated by two connected bell-cranks 99, 100 from a the lock-chamber in pipe 57,.

searea crank 101 osoillated by pinion 102 and rack 103 from the piston of a hydraulic cylinder 104.

'1" he crank 101 (Fig. 5) has, at its outer end, two crank pins 600, one projecting toward 99 and the other toward 105,*the. crank 101 operating in the plane midway between 99 and 105. rFhe upper lever 99 has on its face toward 101 a Ugroove into which one of the crank-pins 600 enters on the upper half of its journey. The lever 105 has a similar 1J groove on its face'toward crank 101, into the end of which the other crank-pin 600 enters upon the lower half of its ourney. The upper half of the journey of the crank 'opens the valves 97 andthe lower half of the journey opens valve 98.V On the u 'per `half of the down-stroke of said `crank t ie valves 97 are Closed, and the opening and closing movement 1s begun "and completed before any movement of the middle valve '98 takes,

The pressure-lock for the fuel includes` al chamber 106 forming part of the outer or remotelcg of the fuel-conduit 35 and having a sloping portion to permit. off-set of the valves, both of which are operated from above. 107 is the upper or entrance valve to this lockchamber and 108 is the lower or exit valve. Each valve has a piston-portion 109 above the. seating portion to prevent fuel from crushingbetween valve and seat and hinder-y ing the seating movement, and a bell-shaped hub 110 to deflect the falling fuel from forcef ful contact with the seating ortion of the valve. The upper valve 107 1s operated by stem 11 1, and toggle 112 from the cross-head of a piston 113 contained in a hydraulic cylinder 114, which is shown in section in Fig. 3. The lower valve 108 is operated by stem 115, and a similar toggle 116 from the piston 151 of a second hydraulic cylinder 117, shown in section in Fig. 16. The slide-valves of the cylinders 111, 117 are operated by' pistonmotors 118, 145 controlled by slide-valves `119, 150, whose rods 120 are connected to rock-levers 121, 122, the former fast to a rock-shaft 123 and the latter to a rocksleeve 124 surrounding said shaft (Fig. 11). Each lever has a toe 125, 126 and the rockshaft and rock-'sleeve have additional toes or lugs 127.` 128. The piston-rod 129 of cylinder 114 has off-set spring-latches 130, 131, the former actuating the toe 12S on the outstroke of rod 12v -andthe latter actuating the toe 125011 the iii-stroke of said rod. The pisonto'the upper ton rods 132 of oylinder 117-has similar oitset latches 133, 134, the former actuating toe 13 5 is ahy-pass connecting the-atmospherio conduit-section 96 with the lock-section 100 and passing around the upper lockvalve 107, said by-pass containing a stopvalve 13o which upon being'oiened, equal.- izes the pressures above and l'ielow said lockvalve and permits theV free opening thereof. A similar by-pass 137, Containing stop-valve 138, connects the lock-chamber 106 above the lower` lock-valve 108 with' the pressuresection of the fuel-conduit below said valve. Of these stop-valves, the upper one 136 is operated through rod 139 and rocker 140 from the rod 141 of the piston-motor 118 pertaining to cylinder 114. The lower stop-valie 138 is operated by a rod 142 and rocker 143 from the rod 144 of the piston-motor 145 pertaining to cylinder 117. The last-said piston-motor 145 also operates the valve 146 (Fig. 3) of the hydraulic ey'lin'der'lU/-t for operating the meter-valves, through rod 14.7, bell-crank 14.8 and rod 149. f

From the above it will he seen that-.a movement of either of the two pilot or 'rider valves 119 (Fig. 3) or 150 (Fig. 16) to* the left will .admit water and cause a movement of the corres onding piston-motor 118 or 145, and theret irough of piston 113 or 151, to the left. It will be ap arent that these two actions cannot take p ace at the saine time. These movements cause alternate openings of the by-pass valves 136, 138, produced by the piston-motors and .slightly preceding .the alternate openings of the lock-valves 107 and 108 respectively. This left-hand movement ot' piston 145 raises valve 146 and therethrough raises the rack 103 with consequent closing of meter-valves 97, 97 and opening of metervalve 98. The left-hand movement of pistons 113 and 151'efl'ects the opening ofthe lock-valves r107, 108 through bending of the toggles .112, 116, reacting upon/the fixed journals 602, 603. The left-hand movement of either pilot-valve is caused b v the pistonrod of the others iston, through the inner latch 130 or 133, w iile the right-hand movement of said pilot-valve, causing movements of the parts controlled thereby opposite to the 'movements above-enumerated, is produced by its ownpiston-rod through the outer latch 131 or 134.

The sequence of the foregoing hydraulic devices is as follows:

For the upper look-valve 107,

(1)Pilot-valve119 moves to the left because latch 133 encounters toe 127 as the lower lock-valve is closing.

(2) liston-motorv 118 moves to the left and opens by-pass valve 136.

(3) Piston 113 moves to the left, causing :fcompleted during the time that the lower l the upper lock-valve to o 'en and admit a charge of fuel to the lock-c amber 106. Y As the piston finishes its outward movement latch 131 encounters toe 125 and (4) Pilot-valve 119 nieves to the right.

(5) Piston-motor 118 moves to the right and closes by-pass valve 136. v

(6) Piston 113 moves to the right and closes the upper lock-valven' The foregolng movements are begun and v-:lock-valve is closed, except as the closing movement of said lower valve actuates Vthe pilot-valve 119 as before mentioned.

For .the lower lock-valve 108, f 18(1) Pilot-valve 150 moves to the left because latch 130 encounters toe 128 as the up. er lock-valve closes.

, Piston-motor' 145 moves to the left and (a) .opjens by-pass valve 138, (b) raises valve 146.

(3)fl2iston 151'v moves tothe left, causing l the lower lock-valvetoopenand discharge the of the lock-cha'mberinto the pressure-section of the fuel-conduit. Rack l03ggrises, closing meter-valves 97, '97 and o pf ning meter-valve 98. As the piston 151 '(4) Pilot-va1ve'150 'moves to the right. ,(5)`Pistonmotor, 145 moves tothe right .and (a) closes by-pass valve 138,*(5) de- 401 f. of the two lock-valve apertures by jets of water delivered as either valve approaches its sea't. For the upper lock-valve 107 a pipe 1,52 leads to a corridor 153 from which jetoutlets 154 penetrate the seat of said fuelv'al've. This pipe is controlled by a plugvalve 155 actuated by piston-motor 118, and

.E5 tion of the fuel-conduit is a screw conveyer as' said iston-motor moves to the right the l plug-va ve opens and flushes the'lock-valve ',167 as the latter approaches its seat. For the lower lock-valve 108 a pipe 156 containa flexible section 157 connects with the ho low stem 115 and conducts water to the interior of said valve 108, from which jetoutlets 158 enetrate the seating face of the valve. A p ug-valve 159 controls the pipe -156 and is actuated by piston-motor 145 so as to o en and flush the seat of the lower lock-va ve as said piston-motor moves to the richt and the lock-valve approaches i s seat. This flushing of the seating surfaces cleans said surfaces and permits each lock-valve to close tight.

In the vertical leg 160 of the pressure-sec- 161 tor elevatingthe charges of fuel discharged through the pressure-lock and dc- 'livering them to the generating chamber of the producer. 'l his screw is rotated by wormgear 162, worm 163 and counter-shaft 164.

The conveyer-section. 160 of the fuel-conduit, and the remote section thereof containing the pressure-lock, together form substantially a U in which is maintained a waterseal whose primary function is to prevent the outward passage through the lock of pressure-gas or air from the producer. )Ve may of course employ other liquids than water for the seal, for example a combustible liquid such as oil.

The water-seal is re lenished through an automatic level-contro ler 165 (shown 1n def tail in Fig. 3) and the maximum level of its inner leoP determined thereby. The water is supplied through a ipe 166' entering the lower chamber 167 oi3 the vcontroller casing under control of an admission-valve 168, and said chamber has open connection with the fuel-conduit section 160 through two pipes 169, 170 at different levels.

171 is a valve controlling discharge through a waste-pipe 172. The valves 168, 171 are actuated by opposite movements of a rod 173 attached to a diaphragm 17 4 whose lowerside chamber 175 is subject to beimT cut off pressure-connection with the profrom ducer y the water reaching and covering the lower end of tube 17.6 or` covering' pipe 17 0.. When this occurs, the pressure )elow the diaphragm becomes reducedv by release through a leakage-pipe 177 -controlled by a small valve. A constant pressure is maintained in the upper diaphragmechamber 178 throueh a pipe 179 connecting said chamber with lghe -pressure-section of the fuel-conduit 35 and hence with the interior of the producer. The pipes 169, 170 enter a vestibule 180 to the water-seal section (see Figs. 6 and 7) separated therefrom by a screen 181 and connecting through a slot 182 having a wide lower part and a narrow upper part. )Vater is maintained in the outer eg of the waterseal up to the level of an overflow-pipe 183 which conducts the waste to the unter-jacket of the revolving hearth 41.

So long as the pipe 170 is uncovered, the pressures above and below diaphragm 174 are equalized and a spring 184 raises rod 173, holding open the admission-valve 168 and causing water to feed to the water-seal. The narrow part of the slot 182 acts as a gasthrottle for the pressure passing to diaphragm-chamber 175.- W ien the water reaches such a height with respect to the pipe 170 that the release from chamber 175 through pipe 177 balances the inflow of gas, theressureabove the diaphragm depresses the atter, and the feed is stoppedv y the closing of admission-valve 168. Should the level continue to rise through accretion from whereby a free path for' exit is A threpgh the iower large ortion of t ie orifice l182and the pipe 169. 'tioned thatl the other water-level device 56 seance ther sources, the diaphragm will continue todescend and open the release-valve 171,

rovided t may here be menhere'in vshown is or may be one operating in general in a manner similar tothe controller .from a wabbling cross-head or lever 199 iv All of the water required in the system is supplied by a pump 196 driven by a belt 197 from the countershaft 148. Said pump (Fig. 1,4); has a multiplicity of pistons 198 driven outer end. The screw 203 threads into the er t crank-plate 201. a a v 205, 206 are two abutments onthe same support adjustable radially upon theframe of the machine by a screw`207. 'Theseabutments( are adapted to engage the teeth of the starwheel on opposite sides and they have a free gap between them in which lthe stan `Wheel' is not actuated. The star-Wheel always'works toward this gap and accordingto the position thereof is determined the throw of the cross-head 199 and hence the-stroke of the pistons 198l and the ldelivery of thepump 196. As' the latter .suplplies motive power for the actuation of the ook-valves 107, 108

yand meter-valves '97,',98, it will be seen that an adjustment of thes'crew 207 determines the rate ofy fuel-feed. and influences the rate of gas-production and the qualityof the gas. The water-circuit is by a trunk-pipe 208 from the pump 196V and thence primarily to the meter-cylinder 104 through branch 4209, to-the pilot-valves 4and piston-motors of the l'ockwalfye cylinders '114 and 117 through branch 210, to the fuel-conduit water-seal through branch 166 ,and to the ash-valve cylin der i59'through -branch 211. Secondarily the waste from cylinders 104, '114, 117 and59 passes .bybranches 213, 214, and 215 to a see# ondary trunk-pipe216, from which it is taken to. Supply the producer-jacket 40 through branch 217, and the ash-pit seal throughplranch 218. From the ash-pit no water-res 'eas takes place except through the'ash-lock. Evaporation disposesof the excess. Should the waste. going to pipe 216- be greater than that;- abstracted therefrom through the branches 217,- 218, the excessl goes to the water-seal vin the fuel-conduit through a branch 219 controlled by a valve-device 220. This device contains a balanced valve 221 (Eig. 18) actuated by a diaphragm 222receiving' on its lower side the pressure of con- .duit-216 via branch 219 and on lts upper side the' pressure of a spring 226 and that oftheA a liquid-seal.

pressure comprising apressure predetermined.

troller release-pile 172 if the ,normal level of f the seal should t ereby be' exceeded.

Compressed air, preferably heated and accompanied by steam, passes into the fuel-- vcolumn through the air'pipe 36, and through the fuel into the gas-,generating chamber of the producer. The fuel which has just emerged fromthe water-seal is Wet and Will more or less condense any steam contained in the air-supply, the Water of condensation -falling back into saidseal with the water which drains from the fuel. Such Water 'as passes on With-the fuel into the producer becomes vaporized and aids in .supplying the producer Withthe necessary steam, but much ofthe water drains off and returns to the seal before the fu'el accomplishes its descent into the producer. The entering air and steam may aidvin drying the Ifuel and pre-heating it so as to facilitate .the oxidizing and other reactions in they producer and conserve thev ie'at.

While this inventio'n is believed to apply principally to closed combustion furnaces such as gas-producers', as mentioned in the introduction, wherein solid fuel -is burned with compressed air,I we also recognize its applicability in a broad sense to the feeding, of solids to other closed vessels maintained un. der a gaseous pressure.

1. In a gas-.producer or other closed vessel, the combination of a closed chamber, a.

yconduit for the passage of solid material between the interior and exterior of said chamber, said conduit having a mechanical. presrial thereto, said conduit mc uding a pressurelock, and means for maintaining a liquid-seal n 3. An apparatus for making gas underhigh l gas-producer, means for sup lying compressed air thereto,

anda fuel-fee conduit therefor including fi. Anapparatus 'for making gas under high pressure comprising a high-pressure gasproducer, a fuel-conduit therefor a liquidseal in said conduit and means for automatically` preserving the -liquid in said seal at a evel. l

5.- Inaggas-producer or other closed ves- ',sel, the :combination of| a closed chamber, a

liquid-seal therefor,

means for dropping solid.

:material by gravity into said seal, and mech- 130 'anism for elevating said material from the 1t into the upper end of said seal to introduce chamber. y

J6. In a gas-'producer or other closed vessel,

the combination of a chamber closed to the atmosphere, a conduit for feeding solid material thereto, means for maintaining a liquid-seal in said conduit,means for automatically feeding solid material into said seal, and separate means for feeding the material out of said'seal into the chamber.

In a gas-producer or other closed vessel, the lcombination of a closed chamber, a conduit fory feeding solid material thereto, a pressure-lock in lsaid conduit, and means for automatically operating said lock at predetermined intervals. i

8.-..Apparatu`s for making gas under high pressurecomprising a combustion-chamber closed to 'the atmosphere, a fuelconduit therefor including aipressure-locl, and means forautomatically and intermittently feeding predetermined separate charges of solid fuel through said lock into the pressure-space of the producer.

9. In a gas-producer or other closed vessel, the combination of Va closed chamber, a' conduit for feeding solid material thereto, apressure-lock in said conduit having entrance and exit valves, and means for automatically operating said valves alternately at predetermined intervals.

10. In a gas-producer or other closed vessel, the combination of a closed chamber, a U-conduit for supplying'solid material thereto, a pressure-lock in the remote leg of said conduit, and means .for maintaining a liquid seal in said lock.` A

11. In a gas-producer or other closed vessel, the combination of a closedchamber, a U-conduit-for supplying solid material thereto, a liquid-seal in said conduit, a pressurelock' in the remote leg of said conduit, and means for automatically maintaining a predetermined liquid level inthe leg nearer to the chamber.

12. The combination of a closed chamber, a U-shaped conduit for feeding solid material thereto, means for supplying a liquid to said conduit to seal the same, and a liquid 4overoW-outlet from the remote leg of the U.

13. .The combination of a closed chamber, a U-shaped conduit for feeding solid material thereto, means for supplying a liquid to said conduit to seal the same, and means for automatically maintaining a predetermined level of the liquidin both legs of theU.

1.4. In a gas-producer or other closed vessel, the combination of` a pressure chamber, a conduit for feeding solid material thereto having a Water-seal bend, alternately-opcrating llock-valves in said conduit, and means to automatically maintain a predetermined Water-level in said bend.

15. The combination ofa pressure chamber, a conduit for feeding solid material thereto, a pressure -lock in said conduit, meansto automatically operate said lock at predetermined intervals, and means to automatically meter predetermined quantities of material to the lock.4 v

- 16. Apparatusfor making gas under high pressure comprising a high-pressure vas-producer, an automatic fuel-lock therefor, and an automatic fuel-meter anterior to said lock and timed with respect to the latters operation.

17.` The combination of a pressure chamber, a conduit for su )plying solid material thereto, a pressure-loc i in said conduit., and means between said lock and the chamber, for elevatingthe material into the chamber.

18: Apparatus for making gas under high pressure comprising a high-pressure gasproducer, a fuel-supply conduit therefor, a iquid-seal in said' conduit, and means to elevate the fuel from said seal into the producer. A

19. Apparatus for making gas under high pressure comprising a high-pressure gas-producer, a U-shaped fuel-sup ly conduit therefor, means to maintain a liquid seal in said conduit, a pressure-lock in the remote leg of said conduit, and a fuel-feeder in the nearer leg thereof.

20. In a gas-producer or other closed vessel, the combination of a pressure chamber, a pressure-lock therefor having an automatically-operated valve, and means for automatically eq'ualizing the pressures on opposite sides of said valve prior to the opening thereof. l

21. In a gas-producer or other closed vessel, the combination of a pressure chamber, a pressure-lock therefor provided with an automatically-operated valve and a water-seal, a

.by-pass conduit connecting the spacesv on opposite sides of said valve, and an automatic valve in said by-pass timed with the lockvalve.

22. In a gas-producer or other closed vessel, the combination of a pressure chamber having an opening, a pressure-lock associated with said opening, a liquid seal coperating with said lock, and a device associated with `the lock and liquid seal for separating and recovering the gas vwhich accompanies the liquid in the lock.

23. In agas-producer, the combination o f a liquid seal, a chamber in branch connection With said seal for receiving liquid and gas from the seal, and means to separate thegas from the liquid.

24. The combination of a pressure chamber, a conduit for feeding solid material thereto, a valve in said conduit, and means for liquid-fiushing said valve.

25. The combination of a gas-producer, a fuel-supply conduit therefor, a pressure-lock in said conduit including a valve, means for o ilirating said`valve,and meanstiined With 4t j movement of said valve -for autmatically lushingith same With-liquid.

5 seati' with t e movements ofsaid valve for' automatically .liquidflushing the valve-aperture.

27.- 1he 4 combination of a gas-producer pressure-chamber, a conduit for feeding solid material thereto, a valve for said con'- duit having .a valve-seat, y"and means for.

liquid-iiushing said valve-seaty 28 "The combination'of a gas-producer', a seating fuel-valve therefor, means t'o recip- `ate as thevalve 'a proaches its seat for autolmatieally liquidushing the valve-a 'erture to' remove gritfrom between 'saidva ve and 1ts'seat.

,fuelsu ply conduittherefor, a pressurelock in sai conduit including alternately-oper- ."atingentrance and eXit-v'alves, and -means toi" automatically li uid-flush' each 'valvel'25 aperture when' its va ve is open. 30. Th combination of a .high-pressureves in'said conduit, 4motors for yoperating 5 5 saidA valves, and means. whereby the opera- ,tion' of one of said motorscontrols .that' of another,4 1 i .32. In a gas-producer or other closed ves- `seL-Qth'e combination of a pressure-lock havmotors for actuating said valves, and meansv whereby? each of said motors controls the operationV of the other. 33. In-a 'as-producer or other Aclosed vessel, the coni ination of a Iress'ure chamber, a conduit for feeding solid material lthereto,

alternatel -oplerating lock-valves in s aid con-- c motors 'foi'- operating said valves, valves for said motors, 'and means` duit, hywrau 59' whereby each'motor controls the valve of the other motor.vv

'34. The 'combination of a high-pressure i chamber having a suplply conduit, pressurelock devices in sai mechanism 'for actuating said dev1ces,me

tering devices for said conduit, hydraulic rocate Saidval've, and means timedqto'opek- 29.l rlhe combination of a-gas-producenia' ing alternately-operatingvalves, hydraulic conduit, hydraulic i vices, and means whereby. the last-said 'movements of, the .first-said hydraulic mechflism.

sel, the combination of a; ressure chamber included 1n a gas-pressure me, hydraulic deber, and means whereby the -Waste liquid l'pressure'.line..

' 36. The combination of a high-pressure gas-producer, hydraulic fuel-su ply mechanism therefor, and a Water-seal i) ducer supplied by' the Waste from said hydraulic mechanism. 37. The combination Vof'a high-pressure gas-producer, hydraulic fuel-supply mechanism therefor, a Water-seal 4for said producer, and means controlledby the pressure .ofthe Waste Water from said hydraulic mechanism for automatically introducing said 4'Waste Water -to vthe lWater-seal.`

a closed gas-generating chamber having an ash-discharge conduit, a'me'chanical presviding a body of Water in said'conduit to seal the lock against the escape of gas during ash-discharge.

39. Apparatus for making. gas under high ressure comprising a down-draft gas-progas having a vdischarge-outlet, means 'to maintain a Water-body in said ash-pit, and a reservoir 4lia-ving a branch vent-and-discharge connection `With the ash-pit controlled by the level of the Water-body.

40. In a gas-producer, the combination of a down-draft closed gas-generating chamber having 'at the bottom a 4gas-outlet and an conduit,'and means for Vrriainta-ining a body of Water in the gas outlet to be traversedby i Witnesses R.,M. 'PIERsom L. T; SHAW.

mechanism for actuating said' metering de,

35. I-n a gas-producer or'otherclosed ves-l y'vices for feeding solid material to said cham-v from said devices. is 'introduced intoA the or said pro- 38. `In a gas-producer, the combination of sure-lookin said conduit, and means for proucer, an ash-pit in thepath of the producerthe gas and' also serving to enter the pressure.

.In Witness Whereoffwe have hereunto set vhydraulic mechanism is controlled. by the 26. The combination of a gas-producer,` a' i fuel-valve therefor, and means timed- 

